Method for Controlling a Digital Device

ABSTRACT

A method for controlling a digital device according to the present application can control the device so as to execute a command corresponding to a single fingerprint or a plurality of fingerprints using a sheet capable of simultaneously recognizing a plurality of fingerprints. Accordingly, a user&#39;s usability can be greatly improved, and a complicated encryption function using a plurality of fingerprints can be implemented, so that the security of the digital device can be greatly improved.

TECHNICAL FIELD

The present invention relates to a method for controlling a digital device, and more particularly, to a method implemented in a digital device equipped with a touch-screen display, which is a method for controlling a digital device capable of recognizing one or more fingerprints using a fingerprint recognition film which can simultaneously recognize a plurality of fingerprints, and executing a command corresponding to a single fingerprint or a plurality of fingerprints, respectively. This application claims the benefit of priority based on Korean Patent Application No. 10-2016-0162148 filed on Nov. 30, 2016 and Korean Patent Application No. 10-2017-0145403 filed on Nov. 2, 2017, the disclosures of which are incorporated herein by reference in their entirety.

BACKGROUND ART

Depending on generalization and use frequency increase of portable mobile devices such as smartphones and tablet PCs, security of these devices is becoming more important. Especially, it is more important to maintain security in electronic commerce and banking fields using these devices. Biological information of a user, for example, fingerprint, iris, face, or voice, can be used to identify or authenticate a device user for security maintenance. In recent years, portable mobile devices to which a user authentication technology through the fingerprint is applied have also been commercialized.

On the other hand, fingerprint recognition methods can be classified into an optical method, an ultrasonic method, an electrostatic capacity method, an electric field measurement method and a heat sensing method, and the like. A digital device to which a conventional fingerprint recognition method is applied requires a separate fingerprint recognition sensor as an essential component, and when a conventional fingerprint recognition sensor is combined with a button of a smart phone or the like, there has been a limitation capable of implanting only a small number of functions in order to implement separate functions in addition to the security function through the fingerprint recognition.

DISCLOSURE Technical Problem

It is an object of the present invention to provide a method for controlling a digital device equipped with a touch-screen display.

It is another object of the present invention to provide a method for controlling a digital device so as to execute a command corresponding to a single fingerprint or a plurality of fingerprints using a sheet capable of simultaneously recognizing a plurality of fingerprints.

It is still another object of the present invention to provide a method for controlling a digital device so as to execute a command corresponding to a combination of a single fingerprint or a plurality of fingerprints and a pressure when a fingerprint over a preset pressure is recognized using a sheet capable of simultaneously recognizing a plurality of fingerprints and a pressure sensor.

The above objects of the present application and other objects can be all solved by the present application which is described in detail below.

Technical Solution

The conventional optical fingerprint recognition method can be divided into a so-called scattering method for detecting light scattered in a ridge portion of a fingerprint in direct contact with a transparent fingerprint contact portion of the device, and a so-called total reflection method for detecting light totally reflected from the surface of a fingerprint contact portion corresponding to a valley portion of a fingerprint. In the former case, since light to be scattered must be detected, it may be difficult to provide a light quantity sufficient to identify the fingerprint pattern to the sensor, and the path of the scattered light may overlap the light path of the original light source, so that the contrast may be lowered. And, in the scattering method, a trapezoidal distortion caused by the light path difference also occurs. Devices having various structures have been proposed to solve the above problems through various papers and patents, but it cannot be said that the scattering method is not suitable for portable mobile devices because of the use of bulky prisms or the like. Also, in the latter case, there is an advantage that a greater light quantity can be secured than a method of detecting scattered light, but if the total reflection path is long in the process in which the totally reflected light toward the sensor repeats the total reflection along the waveguide, the lights totally reflected from adjacent fingerprints may interfere with each other to lower the contrast. In addition, when the conventional total reflection method is used, the size of the device can be increased due to the necessity of separately installing a sensor or a prism, and the like, and there is a problem that compatibility with the portable mobile device having a large area display is also poor, because input and output structures of the fingerprint recognition device are very limited, as the sensor is positioned at the opposite end of one end of the waveguide where the light source is positioned.

Also, in general, a touch panel used in a digital device uses an electrostatic or resistive touch sensor, where the electrostatic or resistive touch sensor has a technical limitation that it is difficult to recognize a fingerprint. Therefore, currently used digital devices are equipped with a separate fingerprint recognition device together with an electrostatic or resistive touch panel and generally perform only a limited function such as unlocking the device by using a fingerprint recognition device installed in the device.

The present inventors have found that a single or a plurality of fingerprints can be recognized using an optical fingerprint recognition sheet. When the optical fingerprint recognition sheet is used, the fingerprint can be recognized on the display to reduce the size of a device by requiring no separate fingerprint recognition device. In addition, since a plurality of fingerprints can be recognized on a large area display, security of a digital device can be greatly improved, and the digital device makes it to execute a command corresponding to a single fingerprint or a plurality of fingerprints only by touching the fingerprint on the display, whereby it is possible to provide a method for controlling a digital device in which the user's convenience is greatly improved.

In order to solve the problems of the prior art described above and to achieve the above objects, the present application provides a method for controlling a digital device using a sheet capable of simultaneously recognizing a plurality of fingerprints, which comprises, in a single layer, a first light control part capable of providing light always totally reflected from a surface layer of the sheet; and a second light control part capable of providing light whose total reflection is determined according to a fingerprint pattern in contact with the surface layer of the sheet to the surface layer of the sheet by changing a part of the light provided from the first light control part and totally reflected from the surface layer of the sheet at a predetermined angle and emitting it.

Advantageous Effects

The method for controlling a digital device according to the present application can control the device to execute a command corresponding to a single fingerprint or a plurality of fingerprints using a sheet capable of simultaneously recognizing a plurality of fingerprints. The sheet of the present application is a sheet which can provide fingerprint information with high contrast and recognize a plurality of fingerprint patterns without any influence on each other, where it can be applied to a digital device having a large area screen display device, thereby greatly improving the user's usability, and it can implement a complicated encryption function using a plurality of fingerprints, thereby greatly improving the security of the digital device.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 schematically shows a cross-section of a sheet for optical fingerprint recognition according to one embodiment of the present application and a device comprising the same.

FIG. 2 is an image of a fingerprint photographed using a sheet according to one embodiment of the present application.

FIG. 3 is a schematic diagram showing fingerprint recognition according to one embodiment of the present application.

Hereinafter, a sheet according to one embodiment of the present application and a device comprising the same will be described in detail with reference to the accompanying drawings. For ease of explanation, the size or shape of each configuration shown may be exaggerated or reduced.

BEST MODE

The present application relates to a method for controlling a digital device. In the present application, the term digital device includes, for example, all devices that perform at least one or more of transmission, reception, processing and output of data, contents, services, applications, and the like. The digital device can be subjected to pairing or connecting (hereinafter, referred to as ‘pairing’) with another digital device, an external server, or the like through a wire/wireless network, thereby transmitting/receiving predetermined data. At this time, if necessary, the data may be appropriately converted before the transmission/reception. The digital device may include, for example, both of a standing device such as a network TV, an HBBTV (hybrid broadcast broadband TV), a smart TV, an IPTV (internet protocol TV) and a PC (personal computer), and a mobile device (or handheld device) such as a PDA (personal digital assistant), a smartphone, a tablet PC and a notebook.

An exemplary digital device control method of the present application may be a method implemented in a digital device having a touch-screen display. The touch-screen display may comprise a sheet capable of simultaneously recognizing a plurality of fingerprints, the sheet may be a sheet comprising: a lower base layer; and a light control layer positioned on the lower base layer and having a first light control part and a second light control part, the first light control part may be provided so as to emit the light that is incident on the lower surface of the first light control part at a first incident angle (θ₀) as the light with a second incident angle (θ_(A)) different from the first incident angle (θ₀) and the second light control part may be provided so as to emit the light that is incident on the upper surface of the second light control part at the second incident angle (θ_(A)) as the light with the second incident angle (θ_(A)) and the light with a third incident angle (θ_(B)) different from the second incident angle (θ_(A)). As described below, the sheet may be a sheet which can comprise a base layer having a different refractive index from each other, emit light incident at a first incident angle as light with a second incident angle different from the first incident angle and recognize a fingerprint on the display. In one example, the sheet of the present application may be an optical fingerprint recognition film.

FIG. 3 is a schematic diagram showing a digital device to which the control method of the present application is applied. The control method of the present application is a control method of a digital device (1) having a touch-screen display, where the touch-screen display may comprise a sheet (2) capable of simultaneously recognizing a plurality of fingerprints (10, 20, 30). The control method may comprise a step of recognizing one or more fingerprints and executing a command independently corresponding to a single fingerprint or a plurality of fingerprints. The method for controlling a digital device of the present application can simultaneously recognize a plurality of fingerprints using the sheet and thus control the digital device so as to execute various commands stored therein only by touching the fingerprint on the display, thereby greatly improving the user's usability. In addition, since the fingerprint can be directly recognized on the display, it is possible to reduce the volume of the digital device without any separate fingerprint recognition device, thereby making it possible to miniaturize the product as compared with the case of using the conventional fingerprint recognition device.

In one example, the control method of the present application can execute a corresponding command by applying one or more heuristic methods to one or more recognized fingerprints. In the present application, the term heuristic method (approximation, discovery or intuition method) may mean a hypothetical decision based on a probability and may mean a statistical algorithm for determining a command corresponding to a user's specific behavior. For example, when the user sweeps on a touch-screen the screen to the left, the heuristic method may mean a method such as a method of moving the screen by determining the user's intention even if the user does not move it horizontally exactly.

Also, in the control method of the present application, one or more heuristic methods may be a heuristic method for determining a corresponding command for a single fingerprint or a combination of a plurality of fingerprints, respectively. In the case of executing the corresponding command independently by applying one or more heuristic methods to a single fingerprint or a plurality of fingerprints, even when the entire fingerprint is not recognized and only a part of the fingerprint is recognized or when positional information on a plurality of fingerprints is different, it is possible to execute a command corresponding to the user's intention, thereby improving the user's usability.

In one example, a command independently corresponding to a single fingerprint or a plurality of fingerprints may comprise unlocking the digital device. In the present application, the fact that a command is independently corresponding to a fingerprint may mean a state in which the same command and/or different commands are inputted to be executed for an individual fingerprint or a combination of different fingerprints. In the present application, the locking of the digital device may mean a locked mode state implemented for the purpose of avoiding activation due to the user's carelessness, or security. In the locked mode state, the digital device may be in an unusable state other than a limited function such as an emergency call. The control method of the present application can simultaneously unlock a digital device by simultaneously recognizing a plurality of fingerprints and implement a complicated encryption function using the plurality of fingerprints. This can enhance the security of digital devices.

In one example of the present application, the command independently corresponding to a single fingerprint or a plurality of fingerprints may be execution of an application. The application may mean a program run on a digital device, which may be exemplified by a utility program, a viewer program and/or a game, and the like, running on the digital device, but is not limited thereto. An exemplary application may include telephone, video conferencing, email, instant messaging, blogging, digital photography, digital video recording, web browsing, digital music playback, digital video playback or digital keyboard playing, but is not limited thereto. By independently executing an application for a single fingerprint or a plurality of fingerprints of a user, the user can run the desired application with a single touch to greatly improve usability.

In another example of the present application, the command independently corresponding to a single fingerprint or a plurality of fingerprints may be a one-dimensional vertical screen scrolling command, a two-dimensional screen translation command, a screen enlargement or reduction command, a command to convert from displaying a first item in an item set to displaying a next item in the item set or a command to convert from displaying a first item in an item set to displaying a previous item in the item set, but is not limited thereto.

In one example, the control method of the present application may further comprise a step of inputting a command corresponding to a single fingerprint or a plurality of fingerprints by a user. The command may be a command previously input into the digital device by the user, which may be a command selected by the user or a command optionally designated by the user among commands previously input in the digital device of the present application. As the user selects a command to be executed on the individual fingerprint or the plurality of fingerprints as above, it is possible to be controlled so as to execute a command that the user wants on the individual fingerprint or the plurality of fingerprints, thereby improving the usability for the digital device.

In another example of the present application, the touch-screen display may comprise a pressure sensor on the back of the display. When a fingerprint is contacted on the display, the pressure sensor may mean a sensor capable of measuring a pressure applied to the display from the fingerprint. The pressure sensor is not particularly limited as long as it can sense the degree of pressure applied to the display. An exemplary pressure sensor may include a capacitive pressure sensor, a piezoelectric pressure sensor, a microelectromechanical system (MEMS)-based pressure sensor, a pressure transducer, a silicon-based pressure sensor, a strain gage, an optical pressure sensor, an inductive pressure sensor, or pressure sensors implemented using other suitable pressure sensing techniques, but is not limited thereto.

When the digital device of the present application comprises a pressure sensor, the digital device may have a preset pressure value. The pressure value may mean an intensity of contact of the fingerprint applied on the touch-screen display, and may mean a force per unit area of the contact. The preset pressure value may be any value set by the user, which may have different values depending on individual users.

In one example, when a fingerprint over a preset pressure of the digital device is recognized, the control method of the present application can execute a command independently corresponding to a combination of a single fingerprint or a plurality of fingerprints and pressure. In addition to the command corresponding to the single fingerprint or the plurality of fingerprints described above, the method executes a command independently corresponding to a combination of the single fingerprint or the plurality of fingerprints and the pressure, whereby more various commands can be input and various commands which can be implemented in the digital device can be driven only by touching the touch-screen display.

In another example of the present application, the digital device of the present application may comprise a motion sensor therein. The motion sensor may be a sensor for sensing a user's movement. The motion sensor is not particularly limited as long as it can sense the user's movement. An exemplary motion sensor can be exemplified by a 3-axis accelerometer, a 3-axis gyroscope, a geomagnetic sensor, and the like, but is not limited thereto.

When the digital device of the present application comprises a motion sensor, the control method of the present application can execute a command independently corresponding to a single fingerprint or a plurality of fingerprints and a user's movement. In addition to the command corresponding to the single fingerprint or the plurality of fingerprints described above, the method executes a command independently corresponding to a combination of the single fingerprint or the plurality of fingerprints and the user's movement, whereby more various commands can be input and various commands which can be implemented in the digital device can be driven only by touching the touch-screen display.

Subsequently, a fingerprint recognition sheet applied to the control method of the digital device of the present application will be described.

In one example related to the present application, the sheet of the present application may be a sheet for optical fingerprint recognition or a sheet for fingerprint input. As described below, the sheet of the present application can be configured so that light derived from an external light source can be present (incident) on the sheet surface layer with two lights (rays) with different angles. One of the lights (rays) can be always totally reflected in the sheet, and the other can be identified by the sensor positioned on the lower part of the sheet, by being determined for total reflection at the surface layer of the sheet depending on a pattern of a material contacting the outside of the sheet and penetrating the lower part of the sheet after being totally reflected.

In this regard, FIG. 1 schematically shows a cross-section of a sheet for optical fingerprint recognition according to one embodiment of the present application and a device comprising the same. The present application will be described with reference to FIG. 1 as follows.

The sheet of the present application may comprise a lower base layer and a light control layer positioned on the lower base layer. In the present application, the term “on” or “above” used in connection with the interlayer lamination position may mean including not only the case where a configuration is formed directly on another configuration but also the case where a third configuration is interposed between these configurations.

The light control layer comprises a first light control part and a second light control part. The light control parts may be configurations provided so as to perform a predetermined function only on light incident at a specific angle. Accordingly, as described below, the first light control part can provide light that always totally reflects to the surface layer of the sheet. Furthermore, the second light control part can provide to the surface layer of the sheet light in which the total reflection is determined depending on a fingerprint pattern in contact with the sheet surface layer.

As shown in FIG. 1, the first light control part can emit the light incident at a first incident angle (θ₀) with respect to the lower surface of the first light control part as the light (A) with a second incident angle (θ_(A)) different from the first incident angle (θ₀). In one example, the exit surface of the first light control part, from which the light with the second incident angle (θ_(A)) is emitted, may be any other surface other than the lower surface of the first light control part. More specifically, the sheet of the present application can be configured so that the light with the second incident angle (θ_(A)) can be emitted from the side surface and/or upper surface of the first light control part. In addition, the second light control part can emit the light incident at a second incident angle (θ_(A)) with respect to the upper surface of the second light control part as both the light (A) with a second incident angle (θ_(A)) and the light (B) with a third incident angle (θ_(B)) different from the second incident angle (θ_(A)). In one example, the exit surface of the second light control part, from which the light with the second incident angle (θ_(A)) and the light with the third incident angle (θ_(B)) are emitted, may be any other surface other than the lower surface of the second light control part. More specifically, the sheet of the present application can be configured so that the light (A) with the second incident angle (θ_(A)) and the light (B) with the third incident angle (θ_(B)) can be emitted from the side surface and/or upper surface of the second light control part. In the present application, the unit of angle is ° (degree), and the term “incident angle” is an angle formed by the traveling direction of light from the normal to the sheet (or light-entering layer or light-entering surface) placed on the horizontal plane, which may mean more than 0° to less than 90°. The term incident angle may also be referred to as an exit angle depending on the relative position of each configuration along the traveling direction of light. In the present application, the “lower surface” may mean one surface of a transparent base layer, a light control layer or a light control part which faces or contacts the lower base layer, and the “upper surface” may mean the opposite one surface of a transparent base layer, a light control layer or a light control part, having the relevant lower surface. The lower surface or the upper surface may be referred to as a light-entering surface or an incident surface, and a light-emitting surface or an exit surface, depending on the traveling path of light.

Since the light control layer of the present application can be divided into two parts in which the angle or path of light, and the like can be controlled differently from each other as above, two lights (A and B) having different angles toward the transparent base layer positioned on the light control layer, specifically, with respect to the transparent base layer, and more specifically, the surface layer of the sheet can be provided (emitted), as in FIG. 1. In the present application, the surface layer of the sheet may mean, for example, the upper surface of the transparent base layer in contact with air, or the upper surface of the transparent base layer in direct or indirect contact with an object having a pattern such as a fingerprint.

In one example, the sheet of the present application may further comprise a transparent base layer that a fingerprint can contact. When the sheet comprises a transparent base layer, the transparent base layer may be located on the light control layer. That is, the sheet may sequentially comprise a lower base layer, a light control layer and a transparent base layer. In the present application, the term “transparent” used in relation to the properties of the layer may mean a case where the lower limit of the transmittance to visible light having a wavelength of 380 nm to 780 nm is 65% or more, 70% or more, 75% or more, 80% or more, 85% or more, 90% or more, or 95% or more, and the upper limit is about 100%, which is in a range of less than 100%.

In the case of comprising the transparent base layer, the first light control part can emit the light incident on the lower surface of the first light control part at the first incident angle (θ₀) through the lower base layer as the light with the second incident angle (θ_(A)) different from the first incident angle (θ₀) toward the transparent base layer. In one example, the light with the second incident angle (θ_(A)) can be emitted from the upper surface and/or the side surface of the first light control part. Furthermore, when the transparent base layer is directly positioned on the light control layer, the lower surface of the transparent base layer can be the light incident surface with respect to the light with the second incident angle (θ_(A)).

In the case of comprising the transparent base layer, the second light control part can emit the light incident on the upper surface of the second light control part at the second incident angle (θ_(A)) through the transparent base layer as the light (A) with the second incident angle (θ_(A)) and the light (B) with the third incident angle (θ_(B)) different from the second incident angle (θ_(A)) toward the transparent base layer. In one example, the light with the second incident angle (θ_(A)) and the light with the third incident angle (θ_(B)) can be emitted from the upper surface and/or the side surface of the second light control part. That is, the second light control part can convert a part of the light (A) having an incident angle of θ_(A) into the light (B) having an incident angle of θ_(B). The conversion degree, that is, the ratio, in which the light (A) incident at the angle θ_(A) is converted to the light (B) with the angle θ_(B), is not particularly limited, which may be suitably adjusted in a range of more than 0% to less than 100%. At this time, θ_(A) and θ_(B) may be an (incident) angle that the light emitted from the first light control part and the light emitted from the second light control part have each in the inside of the transparent base layer.

The information of the fingerprint in contact with the transparent base layer can be read by the above configuration. Specifically, a path of light for allowing the fingerprint information to be read according to one example of the present application will be described as follows. That is, the light incident on the first light control part from the light source via the lower base layer is emitted as the light with the angle θ_(A) that can be always totally reflected from the upper surface of the transparent base layer into the inside of the sheet by the first light control part, and the light with the angle θ_(A) emitted from the first light control part is totally reflected from the upper surface of the transparent base layer irrespective of whether or not the fingerprint and the transparent base layer contact, and is incident on the second light control part. And, the second light control part converts a part of the light incident at the angle θ_(A) into the light with the angle θ_(B) and emits the light to the transparent base layer, and the remaining unconverted light is totally reflected from the upper surface of the lower base layer, for example, the interface between the light control layer and the lower base layer. Thereafter, the light with the angle θ_(B) emitted to the transparent base layer is transmitted (or transmitted and scattered) from the ridge of the fingerprint, which is a contact portion of the transparent base layer and the fingerprint, and is totally reflected from the valley of the fingerprint, which is a non-contact portion of the transparent base layer and the fingerprint. The light with the angle θ_(B) totally reflected from the valley portion of the transparent base layer and the fingerprint can pass through the light control layer and the lower base layer, and reach the sensor to be identified. In the present application, the term “interface” may mean a boundary surface between two adjacent layers, or a boundary surface between heterogeneous media placed on a path through which light passes.

According to one embodiment of the present application, in order to perform functions as above, the sheet of the present application may be constituted or provided as follows.

In one example, the first light control part and the second light control part may comprise each a diffractive optical element or a refractive optical element.

The refractive optical element may mean an element having a characteristic in which the traveling direction or angle of light is determined by the refractive index difference with the adjacent medium. When the light control part of the present application is a refractive optical element, the light control part may be configured in consideration of refractive indexes between the respective layers so as to satisfy the optical path described in the present application.

The diffractive optical element may mean an element having a characteristic in which the traveling direction or angle of light is determined by the shape of the pattern and the spacing between the patterns. When the light control part of the present application is a diffractive optical element, the light control part may be configured in consideration of refractive indexes between the respective layers and diffraction patterns so as to satisfy the optical path described in the present application.

In one example, the light control layer of the present application may comprise a diffractive optical element. Specifically, the first light control part and the second light control part may comprise diffractive optical elements having different functions from each other, where the diffractive optical element may be a holographic optical element (HOE) in the form of a film. The holography is a technique for recording an interference pattern in a photosensitive medium to reproduce a three-dimensional image called a hologram. Also, the holographic film may mean a film on which a holographic recording is recorded, and may mean a film capable of recording an interference pattern on a film having very small photosensitive particles using recording light and reproducing it using reproduction light. Since the holographic film may perform the function only for the recorded light and may not perform the required function for light other than the recorded light, when the holographic film is used for the first light control part and the second light control part, it is particularly advantageous to adjust the angle, the optical path and/or the light quantity of light required in the present application.

The holographic film may comprise a photosensitive material as a recording medium. As the photosensitive material, a photopolymer, a photoresist, a silver halide emulsion, a dichromated gelatin, a photographic emulsion, a photothermoplastic or a photorefractive material, and the like can be used. In one example, the holographic film may comprise a photopolymer as a photosensitive material, and may be, specifically, a film consisting only of a photopolymer, or a film with a double-layered structure comprising a photopolymer layer and a substrate for the layer together. In this case, the substrate used together with the photopolymer may be a transparent substrate and may be, for example, a substrate comprising polycarbonate (PC), polypropylene (PP), polyamide (PA), polyethylene terephthalate (PET) or triacetyl cellulose (TAC), and the like, but is not particularly limited.

In one example, the diffraction efficiencies of the first light control part and the second light control part may be the same or different from each other. Specifically, the first light control part may have the same diffraction efficiency in its entire area and the second light control part may also have the same diffraction efficiency in its entire area, where the diffraction efficiencies of the light control parts may be the same or different from each other.

In one example, the first light control part and the second light control part may be some regions formed by changing only angles or diffraction patterns of recording light on one layer, respectively. Alternatively, the light control layer may also be formed by directly attaching the first light control part and the second light control part or by attaching them via another medium, so that the first light control part and the second light control part, which are separately manufacture, may form a single layer.

When the transmittance described above is satisfied, the kind of the transparent base layer is not particularly limited. For example, it may comprise glass or a polymer resin. As the polymer resin, a polyester film such as PC (polycarbonate), PEN (poly(ethylene naphthalate)) or PET (poly(ethylene terephthalate)), an acrylic film such as PMMA (poly(methyl methacrylate)) or a polyolefin film such as PE (polyethylene) or PP (polypropylene) may be used, without being limited thereto. In one example, the transparent base layer may have a configuration in which a number of glass or polymer resins are laminated. Even in the case of having such a laminated structure, the transparent base layer may be provided so as to perform the functions required in the present application and satisfy the following relational expressions.

In one example, the lower base layer may be a pressure-sensitive adhesive layer satisfying refractive indexes and relational expressions to be described below. The kind or composition of the pressure-sensitive adhesive layer is not particularly limited and may be, for example, an acrylic pressure-sensitive adhesive layer or a silicone pressure-sensitive adhesive layer. In another example, the lower base layer may further comprise, in addition to the pressure-sensitive adhesive material, the above-described transparent resin film, where these may function as a substrate for the pressure-sensitive adhesive material, or may be used for the purpose of imparting other functions. Even in the case of having such a configuration, the lower base layer may be provided so as to perform the function required in the present application and satisfy the following relational expressions.

In the present application, the lower base layer, the light control layer and the transparent base layer may have the same or different refractive indexes. In one example, the layers may each independently have a refractive index in a range of more than 1 to 5 or less, or more than 1 to 3 or less, and the interlayer refractive index difference may be 0.0001 to 2 or less. In the case of the light control layer, the refractive indexes of the first light control part and the second light control part can be adjusted to be the same or different in a range that can perform the functions required in the present application.

In one example, the refractive index of the lower base layer may be less than the refractive index of the light control layer and/or the refractive index of the transparent base layer. That is, the lower base layer may be a low refractive layer. Although not particularly limited, when the refractive index relationship is satisfied, the refractive index difference between the lower base layer and the light control layer may be 0.1 or less.

In one example, the transparent base layer may have a higher refractive index than the light control layer. Although not particularly limited, when the refractive index relationship is satisfied, the refractive index difference between the transparent base layer and the light control layer may be 0.05 or less.

In the present application, the thicknesses of the lower base layer, the light control layer, the transparent base layer, or other constituents that may be contained therein is not particularly limited. For example, if the function of the sheet described in the present application is exerted, the thickness of the structure is not limited, where for example, the lower limit may be 0.1 μm or more, or 1 μm or more and the upper limit may be 1,000 μm or less or 500 μm or less.

The sheet of the present application may be configured such that the light with the angle θ_(A) always totally reflected in the sheet may be present. That is, the light with θ_(A) can be always totally reflected from the upper surface of the transparent base layer, and the light with θ_(A) can also be totally reflected from the upper surface of the transparent base layer, can pass through the light control layer from the transparent base layer and can be totally reflected from the upper surface of the lower base layer, for example, the interface between the light control layer and the lower base layer.

Specifically, the sheet of the present application can be configured so that the light with the angle θ_(A) emitted from the first light control part toward the transparent base layer satisfies the following relational expressions 1 and 2. The relational expressions described below can be obtained using Snell's law.

θ_(A)>(180°/π)×sin⁻¹(n ₀ /n ₁)   [Relational Expression 1]

Relational Expression 1 above defines the condition that the light with the angle θ_(A) traveling from the transparent base layer to the air side is totally reflected from the upper surface of the transparent base layer, for example, the interface between the transparent base layer and the air layer. In Relational Expression 1 above, no is 1 as the refractive index of air, and n₁ is the refractive index of the transparent base layer.

θ_(A)>(180°/π)×sin⁻¹(n ₃ /n ₁)   [Relational Expression 2]

Relational Expression 2 above defines the condition that the light with the angle θ_(A) totally reflected from the upper surface of the transparent base layer passes through the light control layer from the transparent base layer and is totally reflected from the upper surface of the lower base layer such as the interface between the light control layer and the lower base layer. In Relational Expression 2 above, n₁ is the refractive index of the transparent base layer, and n₃ is the refractive index of the lower base layer.

In one example, in order to satisfy Relational Expression 2 above, the light with the angle θ_(A) totally reflected from the upper surface of the transparent base layer must penetrate the upper surface of the transparent base layer and/or the light control layer. For example, when the refractive index of the transparent base layer is larger than the refractive index of the light control layer, the total reflection should not occur at the interface between the transparent base layer and the light control layer, and thus θ_(A) must satisfy the following relational expression 3.

θ_(A)<(180°/π)×sin⁻¹(n ₂ /n ₁)   [Relational Expression 3]

Relational Expression 3 above defines the condition that the total reflection does not occur at the interface between the transparent base layer and the light control layer. In Relational Expression 3 above, n₁ is the refractive index of the transparent base layer, n₂ is the refractive index of the first light control part or the second light control part in the light control layer, and n₁ is larger than n₂.

In the present application, the light with the angle θ_(A) may be light totally reflected from the upper surface (contact surface) of the transparent base layer where the transparent base layer and an object contact directly, even when the object having a pattern with a different height contacts the transparent base layer. In order to satisfy this, the angle θ_(A) of the light emitted from the first light control part may satisfy the following relational expression 4.

θ_(A)>(180°/π)×sin⁻¹(n _(h) /n ₁)   [Relational Expression 4]

In Relational Expression 4 above, n₁ is the refractive index of the transparent base layer, and n_(h) is the refractive index of the portion whose the object having a pattern with a different height is in direct contact with the transparent base layer. At this time, the object having a pattern with a different height may be a fingerprint and the portion whose the object having a pattern with a different height is in direct contact with the transparent base layer may be a ridge of the fingerprint. On the other hand, the non-contact portion of the object having a pattern with a different height with the transparent base layer may be a valley of the fingerprint, and since the valley portion is occupied by the air, the refractive index of the valley portion can be regarded as 1 (=n₀).

As described above, in the present application, the sheet is provided so as to be capable of providing the totally reflected light always totally reflected in the sheet so that the light with the angle (θ_(A)) provided from the first light control part satisfies the predetermined relational expressions. On the other hand, in the present application, the light with the angle (θ_(A)) is light in which the total reflection is performed irrespective of whether or not the fingerprint contacts, so that the light quantity in the sheet can be maintained at a certain level. And, as described below, since the light with the angle (θ_(B)) used for fingerprint recognition originates from the light with the angle (θ_(A)), the light with the angle (θ_(B)) for generating the fingerprint image can also have a light quantity kept constant in the sheet irrespective of whether or not the fingerprint contacts.

In the present application, the second light control part may be a configuration to provide light (B) generated regardless of whether or not the fingerprint contacts.

Specifically, the second light control part may be a configuration to provide light with an angle (θ_(B)) at which the total reflection on the upper surface of the transparent base layer is determined depending on the presence or absence of an object existing on the transparent base layer. That is, the light with the angle (θ_(B)) may be light that when the object does not exist on the transparent base layer, it is totally reflected from the upper surface of the transparent base layer, for example, the interface between the transparent base layer and the air, but when the object having a pattern with a different height contacts the transparent base layer, it is transmitted (or transmitted and scattered) from a direct contact portion (ridge) of the object with respect to the transparent base layer.

In one example, the sheet of the present application may be provided so that the light with the angle (θ_(B)) may be totally reflected from the upper surface of the transparent base layer, for example, the interface between the transparent base layer and the air, by satisfying the following relational expression 5. And, when the object having a pattern with a different height contacts the transparent base layer, it may be configured so that the light with the angle (θ_(B)) may be transmitted (or transmitted and scattered) from the upper face portion of the transparent base layer in direct contact with the object, by satisfying the following relational expression 6.

θ_(B)>(180°/π)×sin⁻¹(n ₀ /n ₁)   [Relational Expression 5]

θ_(B)<(180°/π)×sin⁻¹(n _(h) /n ₁)   [Relational Expression 6]

However, in Relational Expressions 5 and 6 above, no is 1 as the refractive index of air, n₁ is the refractive index of the transparent base layer, and n_(h) is a refractive index of a ridge portion in direct contact with the transparent base layer in the object having a pattern with a different height. As described above, since the valley portion in the object having a pattern with a different height, which is a non-contact portion with the transparent base layer, is occupied by the air, the refractive index of the non-contact portion can be regarded as 1 (=no).

Furthermore, in the present application, the sheet may be provided such that the light with the angle (θ_(B)) emitted from the second light control part and incident on the transparent base layer may be totally reflected from the upper surface of the transparent base layer and then penetrate the upper surface of the light control layer. When the refractive index of the transparent base layer is larger than the refractive index of the light control layer, the total reflection must not occur at the interface between the transparent base layer and the light control layer, so that the angle θ_(B) can satisfy the following relational expression 7.

θ_(B)<(180°/π)×sin⁻¹(n ₂ /n ₁)   [Relational Expression 7]

Relational Expression 7 above defines a condition in which the total reflection does not occur at the interface between the transparent base layer and the light control layer. In Relational Expression 7 above, n₁ is the refractive index of the transparent base layer, n₂ is the refractive index of the first light control part or the second light control part in the light control layer, and n₁ is larger than n₂.

In addition, the sheet of the present application may be provided so that when the light with the angle θ_(B) emitted from the second light control part is totally reflected from the upper surface of the transparent base layer, it can penetrate the lower base layer. The light penetrating the lower base layer can be recognized by the sensor. In order that the light capable of penetrating the lower base layer is present in the sheet, when the light with θ_(B) is totally reflected from the surface layer of the transparent base layer and enters the upper surface of the lower base layer via the transparent base layer and the light control layer, the total reflection should not occur at the interface between the light control layer and the lower base layer. In this connection, θ_(B) can satisfy the following relational expression 8.

θ_(B)<(180°/π)×sin⁻¹(n ₃ /n ₁)   [Relational Expression 8]

Relational Expression 8 above defines a condition that the light penetrating the lower base layer is present. In Relational Expression 8 above, n₁ is the refractive index of the transparent base layer, and n₃ is the refractive index of the lower base layer.

When the angle θ_(B) of the light totally reflected from the upper surface of the transparent base layer as above satisfies Relational Expressions 7 and 8 above, the sensor existing in the lower part of the sheet can recognize the light penetrating the lower base layer, as shown in FIG. 1. That is, the sheet of the present application allows the user's fingerprint to be recognized using a method of identifying a difference in light quantity between the light totally reflected from the upper surface of the transparent base layer in contact with air and the light transmitted (or transmitted and scattered) from the contact portion of the transparent base layer and the object among the light with an angle (θ_(B)) emitted from the second light control part.

As such, the present application does not directly use the light always totally reflected in the sheet for fingerprint identification. Specifically, when a part of the light with the angle θ_(A) provided from the first light control part is converted into the light with the angle θ_(B) different from θ_(A) by the second light control part and emitted toward the transparent base layer, so that the always totally reflected light may exist, and the light emitted toward the transparent base layer at the incident angle θ_(B) is totally reflected from the upper surface of the transparent base layer in contact with an external object to the inside of the sheet and transmitted (or transmitted and scattered) to the outside of the sheet, the present application uses the light quantity difference of these lights for fingerprint identification. That is, the difference between the light quantity of the light totally reflected from the non-contact portion with the fingerprint and traveling to the sensor and the light quantity of the light transmitted (or transmitted and scattered) from the contact portion with the fingerprint and reduced, among the lights at the angle θ_(B), is used for fingerprint identification.

Furthermore, in the present application, the light with the angle θ_(B) is generated from the light always totally reflected in the sheet regardless of the presence or absence of the fingerprint. Therefore, in the present application, the light quantity of the light used for identifying the fingerprint can be kept constant by using the light always totally reflecting the inside of the sheet, and consequently, the difference between the light totally reflected from the interface of the transparent base layer and the air, and the light transmitted (or transmitted and scattered) from the direct contact portion of the transparent base layer and the object, among the lights with the angle (θ_(B)), can be more clearly recognized by the sensor. Besides, in the present application, the light totally reflected from the interface between the transparent base layer and the air and the light transmitted (or transmitted and scattered) from the contact portion of the transparent base layer and the object, among the lights with the angle (θ_(B)) generated regardless of the presence or absence of the fingerprint, are used for fingerprint identification, so that even if a number of fingerprint patterns are in contact with the transparent base layer, they can be identified without being influenced by each other.

In one example, a projected area (S1) of the first light control part may be smaller than a projected area (S2) of the second light control part. In the present application, the term “projected area” may mean, on observing the sheet from the upper part or the lower part in a direction parallel to the normal direction of its surface, an area in which the relevant configuration is viewed, and for example, an orthogonal projection area. Therefore, the increase or decrease of the actual area due to the unevenness of the area comparison target configuration or the like is not considered. Although not particularly limited, S1:S2 may be in a range of 5 to 40:60 to 95.

In another example related to the present application, the digital device of the present application may further comprise a light source part. The light source part means a configuration capable of radiating light toward the sheet. The specific configuration of the light source part is not particularly limited as long as the above function can be performed. As in FIG. 1, the light source part may be located on one surface of the sheet lower base layer, more specifically, on the opposite one surface of one surface of the lower base layer where the first light control part contacts. The light incident from the light source part is incident on the first light control part of the light control layer via the lower base layer, whereby the light that can be always totally reflected in the sheet can be provided to the sheet. In one example, the light incident on the first light control part may be vertical to the bottom surface of the first light control part. In the present application, the term “vertical” means a substantial verticalness in a range that does not impair the desired effect, which is used, for example, in consideration of manufacturing error or variation, and the like. At this time, the error or variation may be within ±10°, within ±8°, within ±6°, within ±4°, within ±2°, within ±1°, within ±0.5°, within ±0.2°, or within ±0.1°.

In one example, the device may further comprise a sensor part. The sensor part may mean a configuration for sensing the light penetrating the lower base layer. The configuration of the sensor part is not particularly limited as long as the above function can be performed, where a known sensor can be used. As in FIG. 1, the sensor part may be located on one surface of the sheet lower base layer, more specifically, on the opposite one surface of one surface of the lower base layer in which the second light control part contacts. As described above, the light totally reflected in the transparent base layer portion that directly contacts the fingerprint, except for the totally reflected light in the sheet, can penetrate the lower base layer to reach the sensor part, where the sensor part can recognize the pattern of the object contacting the transparent base layer, that is, the fingerprint, based on the light quantity difference of the reached lights. In one example, the sensor part may be provided to have a transparent property.

In one example, the device may comprise a display and a sensor part simultaneously. In this case, the device may sequentially comprise the sensor part and the sheet, or may sequentially comprise the sensor part, the display and the sheet. In addition, any one of the display and the sensor part may also form one layer with the light source part.

FIG. 2 is an image of a fingerprint photographed using a sheet according to one embodiment of the present application. As the sheet used for photographing, a laminate sequentially comprising a lower base layer having a refractive index of 1.41 for light having a wavelength of 532 nm, a light control layer including a holographic film having a refractive index of 1.50 for light having a wavelength of 532 nm and a glass base layer (cover glass) having a refractive index of 1.51 for light having a wavelength of 532 nm was used. In the case of the light control layer, it was produced using a known photopolymer film. Specifically, a diffraction pattern was recorded on the light control layer, so that the first light control part could emit the incident light with 73° based on the normal to the sheet (transparent base layer) and the second light control part could emit some of the incident light with an angle of 45° based on the normal to the sheet (transparent base layer. Thereafter, the sheet was irradiated with an external light with 0° based on the normal to the sheet (transparent base layer), and the image appearing at the bottom of the lower base layer by contacting a fingerprint with the surface of the transparent base layer was photographed with a CCD (charge-coupled device).

As described above, the invention of the present application has been described with reference to FIGS. 1 and 2 which are exemplary embodiments of the present application, but the scope of protection of the present invention is not limited to the above-described specific embodiments and drawings. In addition, it will be understood by those having ordinary knowledge in the technical field to which the present technical field pertains that the inventions described in the claims can be changed or modified variously within the technical spirit and scope of the present invention as filed. 

1. A method for controlling a digital device, the device comprising: a display comprising an optical fingerprint recognition sheet on a fingerprint contact portion; and a sheet comprising: a lower base layer; and a light control layer positioned on the lower base layer and having a first light control part and a second light control part, wherein the first light control part is provided so as to emit light incident on the lower surface of the first light control part at a first incident angle (θ₀) as light with a second incident angle (θ_(A)) different from the first incident angle (θ₀), and wherein the second light control part is provided so as to emit light incident on the upper surface of the second light control part at the second incident angle (θ_(A)) as light with the second incident angle (θ_(A)) and light with a third incident angle (θ_(B)) different from the second incident angle (θ_(A)), the method comprising: when a single or plurality of fingerprints contact the display of the device, executing a command independently corresponding to the single or a plurality of fingerprints.
 2. The method for controlling a digital device according to claim 1, further comprising, for one or more recognized fingerprints, applying one or more heuristic methods to execute a corresponding command.
 3. The method for controlling a digital device according to claim 1, wherein the command independently corresponding to the single fingerprint or the plurality of fingerprints is a one-dimensional vertical screen scrolling command, a two-dimensional screen translation command, a screen enlargement or reduction command, a command to convert from displaying a first item in an item set to displaying a next item in the item set, or a command to convert from displaying a first item in an item set to displaying a previous item in the item set.
 4. The method for controlling a digital device according to claim 1, wherein the command corresponding to the single fingerprint or the plurality of fingerprints is a command selected by a user or a command designated by a user.
 5. The method for controlling a digital device according to claim 1, wherein the touch-screen display comprises a pressure sensor on the back of the display, and wherein executing the command is based at least in part on pressure sensed by the pressure sensor.
 6. The method for controlling a digital device according to claim 5, wherein the method further comprises, when a fingerprint over a preset pressure of the digital device is recognized, executing a command independently corresponding to a combination of the single fingerprint or the plurality of fingerprints and a pressure sensed by a pressure sensor on a back of the display.
 7. The method for controlling a digital device according to claim 1, wherein the digital device comprises a motion sensor, and wherein executing the command is based at least in part on movement sensed by the motion sensor.
 8. The method for controlling a digital device according to claim 7, wherein the method further comprises, when a user's movement preset in the digital device is recognized, executing a command independently corresponding to a combination of the single fingerprint or the plurality of fingerprints and a user's movement sensed by a motion sensor included in the device.
 9. The method for controlling a digital device according to claim 1, wherein the sheet further comprises a transparent base layer, and comprises the lower base layer, the light control layer and the transparent base layer sequentially.
 10. The method for controlling a digital device according to claim 9, further comprising, emitting the light incident on the lower surface of the first light control part at the first incident angle (θ₀) through the lower base layer as the light with the second incident angle (θ_(A)) different from the first incident angle (θ₀) toward the transparent base layer, and emitting the light incident on the upper surface of the second light control part at the second incident angle (θ_(A)) through the transparent base layer as the light with the second incident angle (θ_(A)) and the light with the third incident angle (θ_(B)) different from the second incident angle (θ_(A)) toward the transparent base layer.
 11. The method for controlling a digital device according to claim 10, wherein each of the first light control part and the second light control part on which the incident light is emitted comprises a respective diffractive optical element or a refractive optical element.
 12. The method for controlling a digital device according to claim 11, wherein each of the first light control part and the second light control part on which the incident light is emitted comprises a respective holographic film.
 13. The method for controlling a digital device according to claim 11, wherein the light with the angle (θ_(A)) emitted from the first light control part is totally reflected from both of the upper surface of the transparent base layer and the upper surface of the lower base layer by satisfying: θ_(A)>(180°/π)×sin⁻¹(n ₀ /n ₁) and: θ_(A)>(180°/π)×sin⁻¹(n ₃ /n ₁) wherein, n₀ is the refractive index of air, n₁ is the refractive index of the transparent base layer and n₃ is the refractive index of the lower base layer.
 14. The method for controlling a digital device according to claim 13, wherein the light with the angle (θ_(A)) emitted from the first light control part is totally reflected from the upper surface of the transparent base layer and then penetrate the upper surface of the light control layer by satisfying: θ_(A)<(180°/π)×sin⁻¹(n ₂ /n ₁) wherein, n₁ is the refractive index of the transparent base layer, n₂ is the refractive index of the first light control part or the second light control part in the light control layer, and n₁ is larger than n₂.
 15. The method for controlling a digital device according to claim 14, wherein when an object having a pattern with a different height contacts the transparent base layer, the light with the angle (θ_(A)) emitted from the first light control part is totally reflected from the upper surface of the transparent base layer that the transparent base layer and the object contact directly by satisfying: θ_(A)>(180°/π)×sin⁻¹(n _(h) /n ₁) wherein, n₁ is the refractive index of the transparent base layer and n_(h) is the refractive index of the portion whose the object having a pattern with a different height is in direct contact with the transparent base layer.
 16. The method for controlling a digital device according to claim 15, wherein when the object having a pattern with a different height contacts the transparent base layer, the light with the angle (θ_(B)) emitted from the second light control part is totally reflected from the upper surface of the transparent base layer in contact with air by satisfying: θ_(B)>(180°/π)×sin⁻¹(n ₀ /n ₁) and the light with the angle (θ_(B)) emitted from the second light control part can penetrate the upper surface of the transparent base layer that the transparent base layer and the object contact directly by satisfying: θ_(B)<(180°/π)×sin⁻¹(n _(h) /n ₁) wherein, n₀ is 1 as the refractive index of air, n₁ is the refractive index of the transparent base layer and n_(h) is the refractive index of the portion whose the object having a pattern with a different height is in direct contact with the transparent base layer.
 17. The method for controlling a digital device according to claim 1, wherein the sheet is provided such that the light with the angle (θ_(B)) emitted from the second light control part is totally reflected from the upper surface of the transparent base layer and then penetrate the upper surface of the light control layer by satisfying: θ_(B)<(180°/π)×sin⁻¹(n ₂ /n ₁) wherein, n₁ is the refractive index of the transparent base layer, n₂ is the refractive index of the first light control part or the second light control part in the light control layer and n₁ is larger than n₂.
 18. The method for controlling a digital device according to claim 17, wherein the light with the angle (θ_(B)) emitted from the second light control part is totally reflected from the upper surface of the transparent base layer to penetrate the light control layer and the lower base layer by satisfying: θ_(B)<(180°/π)×sin⁻¹(n ₃ /n ₁) wherein, n₁ is the refractive index of the transparent base layer and n₃ is the refractive index of the lower base layer.
 19. The method for controlling a digital device according to claim 1, wherein the digital device further comprises a light source part and the light source part is located on the opposite one surface of one surface of the lower base layer where the first light control part contacts.
 20. The method for controlling a digital device according to claim 19, further comprising the light source part emitting vertical light to the first light control part. 